Support element

ABSTRACT

Provided is a wood splitter having a support element, a first elongated element, a second elongated element, and wood splitting components. A support element may be a first elongated element and a second elongated element engaged to the first elongated element. The first elongated element may be subject to a first pre-stress load. The first pre-stress load may be a first moment. The second elongated element may be engaged to the first elongated element and may be subject to a second pre-stress load. Wood splitting components may be engaged with at least one of a first elongated element or a second elongated element, may be adapted to operate to split wood, and may be adapted to apply an operational load during operation to the first elongated element. The operational load may at least partially relax the first moment.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. Ser. No. 13/706,934, titledSUPPORT ELEMENT, filed on Dec. 6, 2012, which is incorporated herein byreference, and which is a divisional of U.S. Ser. No. 12/619,017, titledSUPPORT ELEMENT, filed Nov. 16, 2009, which is incorporated herein byreference, and which claims priority to U.S. Ser. No. 61/116,316, titledWOOD SPLITTER, filed Nov. 20, 2008, which is incorporated herein byreference.

TECHNICAL FIELD

Provided is a support element. More specifically, provided is a supportelement comprising components having pre-stressed elements that relaxduring loading of the support element. Further provided are machines,mechanisms, and frames comprising a support element.

BACKGROUND

Machines, mechanisms, and frames are very common. It is also common forthe support elements of machines, mechanisms, and frames to be exposedto substantial loads. Exposure to substantial loads militate the supportelements of machines, mechanisms, and frames be capable of withstandingsubstantial loads without mechanical failure.

Unless otherwise noted, as it is used herein, “mechanical failure” isany sort of deformation, including but not limited to, breakage,bending, twisting, fracture, yielding, buckling, necking, or cracking,that substantially diminishes the capability of a support element toperform the function desired of it. Not all deformation is mechanicalfailure; some elastic deformation is unavoidable and some elasticdeformation is to be expected during loading of any real supportelement.

For a support element formed of a given material, the capacity towithstand a given load is a function of, among other factors, thecross-sectional area of the load bearing element.

One common way to increase the capacity of the loads that a supportelement can withstand without mechanical failure is to increase thecross-sectional area of the load bearing element by increasing the sizeof the support element.

Increasing the size of a support element often adds cost. It remainsdesirable to provide relatively inexpensive support element which arecapable of withstanding large loads without mechanical failure.

SUMMARY

This Summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key factors oressential features of the claimed subject matter, nor is it intended tobe used to limit the scope of the claimed subject matter.

Provided is a wood splitter. A wood splitter may comprise a supportelement, a first elongated element, a second elongated element, and woodsplitting components. A support element may comprise a first elongatedelement and a second elongated element engaged to said first elongatedelement. The a first elongated element may be subject to a firstpre-stress load. The first pre-stress load may comprise a first moment.The a second elongated element may be engaged to the first elongatedelement and may be subject to a second pre-stress load. Wood splittingcomponents may be engaged with at least one of a first elongated elementor a second elongated element, may be adapted to operate to split wood,and may be adapted to apply an operational load during operation to thefirst elongated element. The operational load may at least partiallyrelax the first moment.

Further provided is a vehicle suspension. A vehicle suspension maycomprise a support member engaged with a vehicle, a first componentengaged to said support member, a second component engaged to said firstcomponent, and wherein, during operation of said vehicle, said vehicleis adapted to apply an operational load to the first component, andwherein said operational load at least partially relaxes the firstmoment. A first component may comprise a first elongated beam adapted toundergo substantial deflection in a substantially elastic manner, afirst engagement element, and a third engagement element. The firstcomponent may be subject to a first pre-stress load, wherein the firstpre-stress load comprises a first moment and wherein said first momenttends to bend the first elongated beam into an arcuate form. The secondcomponent may comprise a second elongated beam adapted to undergosubstantial deflection in a substantially elastic manner, a secondengagement element, engaged to the first engagement element by a firstconnection, and a fourth engagement element, engaged to the thirdengagement element by a second connection. The second component may besubject to a second pre-stress load.

Further provided is a bridge for supporting traffic. The bridge maycomprise a first component, and a second component engaged to said firstcomponent. The first component may comprise a first elongated beamadapted to undergo substantial deflection in a substantially elasticmanner a first engagement element, and a third engagement element. Thefirst component may be subject to a first pre-stress load, wherein thefirst pre-stress load comprises a first moment, and wherein the firstmoment tends to bend the first elongated beam into an arcuate form. Thesecond component may comprise a second elongated beam adapted to undergosubstantial deflection in a substantially elastic manner, a secondengagement element, engaged to the first engagement element by a firstconnection, and a fourth engagement element, engaged to the thirdengagement element by a second connection. The second component may besubject to a second pre-stress load. During loading of the bridge bytraffic, an operational load may be applied to the first component. Theoperational load may at least partially relax the first moment.

To the accomplishment of the foregoing and related ends, the followingdescription and annexed drawings set forth certain illustrative aspectsand implementations. These are indicative of but a few of the variousways in which one or more aspects may be employed. Other aspects,advantages and novel features of the disclosure will become apparentfrom the following detailed description when considered in conjunctionwith the annexed drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

What is disclosed herein may take physical form in certain parts andarrangement of parts, and will be described in detail in thisspecification and illustrated in the accompanying drawings which form apart hereof and wherein:

FIG. 1 shows a side view of a portion of a wood splitter.

FIG. 2 shows an end view of a portion of a wood splitter.

FIG. 3 shows a side elevation of a wood splitter with an adapter.

FIG. 4 shows a cross-section of a portion of an adapter.

FIG. 5 shows a side view of a portion of a wood splitter with anadapter.

FIG. 6 shows an elongated connecting member.

FIG. 7 shows a perspective view of a cross-section of a portion of anadapter.

FIG. 8 shows a front view of one implementation of a support member.

FIG. 9 shows a front view of another implementation of a support member.

FIG. 10 shows a front view of another implementation of a supportmember.

FIG. 11 shows a front view of another implementation of a supportmember.

DETAILED DESCRIPTION

The claimed subject matter is now described with reference to thedrawings, wherein like reference numerals are generally used to refer tolike elements throughout. In the following description, for purposes ofexplanation, numerous specific details are set forth in order to providea thorough understanding of the claimed subject matter. It may beevident, however, that the claimed subject matter may be practicedwithout these specific details. In other instances, structures anddevices may be shown in block diagram form in order to facilitatedescribing the claimed subject matter.

Machines, mechanisms, and frames may include any sort of machines,mechanisms, and frames. Without limitation, the category of machines,mechanisms, and frames comprises wood splitters, mechanical clocks,vehicle suspensions, and bridges. As used herein, unless otherwisenoted, the elements of machines, mechanisms, and frames that are adaptedto support loads as part of their function are “support elements”.

The support elements of machines, mechanisms, and frames may be subjectto substantial loads. Substantial loads to which they are subjectmilitate that the support elements be capable of withstandingsubstantial loads without mechanical failure.

As used herein a load may comprise, a compressive force, a tensileforce, a shear force, a positive moment, a negative moment, a twist, andcombinations thereof. Support elements may be subject to many kinds ofloads including, without limitation, those comprising a compressiveforce, a tensile force, a shear force, a positive moment, a negativemoment, a twist, and combinations thereof.

Without limitation, a support element may be comprised of castcomponents, extruded components, injection molded components, forgedcomponents, and combinations thereof. A support element may be comprisedof metals, ceramics, polymers, cementitious materials, glasses, or othermaterials. Metals may comprise iron, iron alloys, steel alloys,stainless steel alloys, aluminum, aluminum alloys, bronze alloys, brassalloys, copper, copper alloys, and combinations thereof.

In certain implementations support elements comprise members selectedfrom the group comprising I-beams, square beams, rectangular beams,channels, angles, plates, tubes, straps, rods, and combinations thereof.A support element may comprise materials selected from the groupcomprising metal, wood, concrete, polymers, and combinations thereof. Incertain implementations, a support element comprises steel materials.

Many common engineering components have no or very little residualstress in their rest state. Unless otherwise noted, as used herein “reststate” will refer to the state of a support element in a machine,mechanism, or frame, such as, without limitation, a wood splitter,bridge or suspension, and its sub-components when the machine,mechanism, or frame is not in operation, use, or under a load. By way ofcomparison when a machine, mechanism, or frame, such as, withoutlimitation, a wood splitter, bridge or suspension, is in operation, use,or under a load, operational loads or dynamic loads may appear in asupport element of the machine, mechanism, or frame that are absent atthe rest state.

It is possible to pre-stress components such that they bear asubstantial amount of stress while in their rest state. This can be doneby means including but not limited to, engaging a first stressedcomponent to one or more other components such that the first stressedcomponent is prevented from relaxing by the other components. In firstnon-limiting example, an arced component, that is, a component which isarcuate when fully relaxed, may be elastically deformed and engaged to aflat component such that at least some of the elastic deformation of thearced component is prevented from relaxing by the engagement. In secondnon-limiting example, a rod may be engaged with a tube such that the rodis in tension and the tube is in compression. In this second example,both the rod and the tube become pre-stressed components by thedescribed arrangement.

Engagement of components may be by any acceptable engineering means.Acceptable means include, but are not limited to, welding, bolting,pinning, and brazing. Acceptable means may also include engagement bymeans of pre-stress loads as described here below.

It is not unusual for pre-stressed components to be engaged with otherpre-stressed components or to induce stress in components with whichthey are engaged. In certain implementations the pre-stress inpre-stressed components are reactions to pre-stress in otherpre-stressed components. A pre-stress created by reaction will be ofsubstantially the same magnitude but opposed to pre-stress creating it.In one non-limiting example, a compressive pre-stress of 3 kN in aconcrete slab may be created by a tensile pre-stress of 3 kN in atensioning cable. Because different materials have different materialproperties, including but not limited to different tensile strengths,different compressive strengths, and different shear strengths, incertain implementations one or more pre-stressed components can providethe desired performance properties more cheaply than one or morenon-pre-stressed components.

Pre-stressed components may be used in support members to withstandgreater loading than would larger and/or more expensive,non-pre-stressed components. In one non-limiting example, given anengineering requirement that an acceptable component not yield duringoperation and an operational load of 250 kN in tension, anon-pre-stressed component formed of material with a yield strength of250 MPa would have to have a minimum cross-section of 10 cm² towithstand the operational load acceptably. By way of comparison, in asecond non-limiting example, given the same engineering requirement thatan acceptable component not yield during operation and the sameoperational load of 250 kN in tension, a pre-stressed component having acompressive preload of 125 kN and formed of the same material, wouldhave to have a minimum cross-section of 5 cm², half the area of thenon-pre-stressed component, to withstand the operational loadacceptably.

As noted above, wood splitters are machines which may comprise a supportelement. Wood splitters are common tree-product processing machines. Awood splitter is a collection of components that operate to split wood.The wood can comprise logs or tree trunks or branches or other wood tobe split for firewood or fence rails or some other purpose. The loadsused in wood splitting operations can be quite large. It is not unusualfor wood splitters to apply loads in excess of 30 tons. Large loadsmilitate the support elements of a wood splitter be capable ofwithstanding large loads without mechanical failure.

Wood splitters typically have a predetermined limit to the length of thepiece to be split. Because rails are typically substantially longer thanpieces of firewood, log splitters sometimes have a predetermined limitto the length of the piece to be split which is much shorter than thattypical to rail splitters. A wood splitter may include an adapter toallow a reciprocating wood splitter to be used for splitting pieces ofwood such as, without limitation, rails which are longer than theexisting stroke length.

Referring now to FIGS. 1-7, FIG. 1 shows a wood splitter 10 engaged witha support element 20. The wood splitter 10 comprises wood splittingcomponents comprising, without limitation, a wedge 12 and a push plate14. The support element 20 comprises a first elongated element 22 and asecond elongated element 26. Without limitation, the wedge 12 may beengaged with the first elongated element 22 by a weld 13. Other meansfor engaging components, such as mechanical fasteners, or brazing, mayalso be acceptable. The push plate 14 is slidably engaged with the firstelongated element 22. The push plate 14 comprises an engagement feature16 by which loads may be applied by a motion imparting element 50 inorder to slide the push plate 14 toward the wedge 12, optionally, alongwith wood to be split (not shown) therebetween. A motion impartingelement 50 may comprise a static element 55 and a dynamic element 57,where the dynamic element 57 moves with respect to the static element55. A motion imparting element may comprise a member selected from thegroup consisting of a hydraulic press, a pneumatic press, a screw, amotor, and an engine. In certain implementations, the engagement feature16 may comprise a hole, a pin, a shaft, a flange, a plate, an abutment,or a key.

A support element can support or engage directly or indirectly otherelements of the wood splitter. In certain non-limiting implementations,a wood splitter may comprise a support element 20 which holds a woodsplitting wedge 12 in a desired position relative to a motion impartingelement 50. In general, a support element 20 such as the one shown inFIG. 1, may be designed to withstand compressive, tensile, and/or shearloads equal to or greater than those expected during operation of thewood splitter 10.

A push plate 14 may be any component which can load wood pieces to besplit against the wedge 12. The push plate 14 is not limited to planaror substantially planar components. In certain implementations the pushplate 14 may comprise a plate, a wedge, a cone, a pyramid, orcombinations thereof.

The force required to split the wood (not shown) will deliver equivalentreaction forces to the wedge 12 and to the push plate 14. That is,whatever force is applied to the wood (not shown) as the push plate 14and the wedge 12 are forced together, an equivalent opposing force isapplied by the wood (not shown) to the wedge 12 and the push plate 14.Stated another way, in operation, the push plate 14 and the wedge 12 actto do positive work on the wood (not shown) while the wood (not shown)does negative work on the push plate 14 and the wedge 12. Accordingly,the wedge 12 and the push plate 14 must be engaged to some form of guideor frame or structure or support element 20 capable of holding the wedge12 and the push plate 14 substantially in place or moving them againstthe forces applied to them during operation of the wood splitter 10. Incertain implementations the wood splitter 10 comprises a support element20 adapted to hold some of the components comprising the wood splitter10 substantially in place relative to one another. In certainimplementations the wedge 12 and the push plate 14 are engaged to asupport element 20 to hold the wedge 12 and the push plate 14substantially in place relative to one another against the forcesapplied to them during operation of the wood splitter 10.

Without limitation, an example of operational forces in a mechanizeddevice are the operational loads which are exerted on the wedge 12 andpush plate 14 of a wood splitter 10 during operation.

FIG. 2 shows a wood splitter 10 engaged with a support element 20. Thesupport element 20 comprises a first elongated element 22 and a secondelongated element 26. Without limitation, first elongated element 22 anda second elongated element 26 may be engaged by a weld 24. Acorresponding weld (not shown) may engage the other ends of the firstelongated element 22 and a second elongated element 26. As noted above,other engagement means in the alternative to or in combination withwelds may be equally acceptable. In certain implementations, a firstelongated element may be subject to a substantial pre-stress load. Inthe implementations shown, without limitation, the first elongatedelement 22 is arcuate when full relaxed but is pulled into a flatter,pre-stressed state by engagement with second elongated element 26. Inthe orientation in which it is shown, the relaxed state of the firstelongated element 22 is concave downward. In certain implementations,without limitation, the first elongated element 22 may be subject to apre-stress load comprising a moment. In certain implementations, withoutlimitation, the first elongated element 22 may be subject to apre-stress load comprising a moment in excess of 1 kN-m, in excess of 5kN-m, in excess of 10 kN-m, or in excess of 20 kN-m.

During operation, the first elongated element 22 will be subjected tooperational loading opposite that of its pre-stress loading. That is,the wedge 12 and the push plate 14, being above the support element 20will be subject to forces which will apply a negative moment to thesupport element 20. The negative moment will tend to bend the supportelement 20 in a downward concave curve. That is, the addition of theoperational loading to the support element 20 will cause the firstelongated element 22 to relax into a shape more similar to that of itsfully relaxed arcuate concave downward shape. That is, duringconventional operation, as the other elements of the wood splitterassembly such as, without limitation, second elongated element 26 aresubjected to operational loads during operation, the net stress in thefirst elongated element 22 will be reduced.

FIGS. 3-7 show a wood splitter adapter 30. The wood splitter adaptercomprises an elongated mounting bracket 36, a deck 34, an elongatedconnecting member 40, discrete connection points 44, and a secondarypush plate 32. In certain implementations, the elongated mountingbracket 36 may be engageable to a support element 20 of a wood splitter.In certain implementations, the elongated mounting bracket 36 may beengaged to the support member 20 such that the axis of elongation of theelongated mounting bracket 36 is parallel to one or more of the axes ofelongation of the first elongated element 22 and a second elongatedelement 26 comprising support member 20. In certain implementations,deck 34 may be engaged to a secondary push plate 32 by welding, bolting,brazing, or any other acceptable engagement method. In certainimplementations, deck 34 may be slidably engaged with the elongatedmounting bracket 36. In certain implementations, deck 34 may be adaptedto slide along an axis parallel to the axis of elongation of theelongated mounting bracket 36. In certain implementations, the elongatedconnecting member 40 may comprise a first end 40 a adapted forengagement with the primary push plate 14 and a plurality of discreteconnection points 44. In certain implementations, the elongatedconnecting member 40 may be slidably engaged with deck 34. In certainimplementations the plurality of discrete connection points 44 are eachadapted to engage with an engagement feature 33 of deck 34. In certainimplementations, the engagement of elongated connecting member 40 withdeck 34 may be selectable between a slidably engaged state or areleaseably fixed state by the selective engagement of any of aplurality of discrete connection points 44 with the engagement feature33. Selective engagement of any of a plurality of discrete connectionpoints 44 with the engagement feature 33.

With continued reference to FIGS. 3-7, in one implementation, withoutlimitation, a wood splitter adapter 30 allows a wood splitter 10 to beused to fully split elongated pieces of wood (not shown) that are longerthan the stroke length of the wood splitter 10 along the elongated axis(not shown) of the wood piece (not shown). In one implementation,without limitation, a wood splitter adapter 30 comprises an adjustablesecondary push plate 32 engageable to the existing or primary push plate14. The secondary push plate 32 may be engaged to the existing orprimary push plate 14 with an elongated connecting member 40. Theelongated connecting member 40 may comprise a first end 40 a adapted forengagement with the primary push plate 14. The elongated connectingmember 40 has a plurality of discrete connection points 44 that allowadjustable engagement between the elongated connecting member 40 and theengagement feature 33. In certain implementations adjustable engagementbetween the elongated connecting member 40 and the engagement feature 33may allow the distance between the first end 40 a of the elongatedconnecting member 40 and the secondary push plate 32 to be selectedamong a plurality of discrete distances. In certain implementations thediscrete connection points 44 comprise adaptations for engagement withmechanical fasteners. The mechanical fasteners may comprise pins, bolts,keys, nuts, clips, clamps, and other mechanical fasteners. Theadaptations for engagement with mechanical fasteners may comprise holesfor accepting pins, holes for accepting bolts, keyways, shafts, threads,or other adaptations. The discrete connection points 44 may be spacedapart by a distance 46 equal to or less than that of the existing strokelength of the wood splitter 10 making at least some of theabove-referenced plurality of discrete distances differ by amounts equalto or less than that of the existing stroke length of the wood splitter10.

Selection of a first discrete connection point 44 allows the adjustablesecondary push plate 32 to be located a sufficient distance from thewedge 12 to accommodate pieces of wood of the desired length. Inoperation the wood splitter 10 drives the primary push plate 14, and, byengagement, the secondary push plate 32 some distance closer to thewedge 12 where the distance is equal to or shorter than the existingstroke length of the wood splitter 10. The apparatus described in thisimplementation can be operated so that there are a plurality of discreteconnection points 44 in the region defined by the stroke length. Thisapparatus may be adapted to perform a cycle comprising the steps of 1)moving primary push plate 14 and, thereby, moving the engaged adapter,secondary push plate 32, and the associated wood piece closer to thewedge 12, 2) breaking the connection at a discrete connection point 44between the elongated connecting member 40 and the primary push plate14, 3) moving the primary push plate 14 to a location further from thewedge 12 and closer to the secondary push plate 32, 4) establishing aconnection at another discrete connection point 44 between the elongatedconnecting member 40 and the primary push plate 14.

As noted above, it is also possible to engage components by means ofpre-stress forces. In certain non-limiting implementations, at least onecapturable component and at least one captured component are engaged insuch a way that at least one of the components must be stretched,stressed, deformed, loaded, or have further energy of deformationsomehow added to the component in order to disengage the components. Insome implementations at least one of the components is stretched,stressed, deformed, or otherwise loaded such that it contains energy ofdeformation and is held in the stretched, stressed, deformed, orotherwise loaded state by one or more other components.

Referring now to FIGS. 8-9, in certain implementations, and withoutlimitation, a support member 80, 90 may comprise a first component 81,91 and a second component 82, 92. First component 81, 91 may beelastically deflectable such that it has some of the properties of aspring. In certain implementations, such as, without limitation, thatshown in FIGS. 8-9, first component 81, 91 comprises a first beam 84, 94adapted to undergo substantial deflection in a substantially elasticmanner and a first engagement element 85, 95. Second component 82, 92 isadapted to hold first component 81, 91 in a deflected position. Incertain implementations, first component 81, 91 is adapted to holdsecond component 82, 92 in a deflected position. Engagement is made bydeflecting the first component 81, 91 to produce a reaction force andcapturing the first component 81, 91 with a second component 82, 92 suchthat either the first component 81, 91 or the second component 82, 92must be further loaded or otherwise acted upon in order to disengage thefirst component 81, 91 from the second component 82, 92.

In certain implementations, such as, without limitation, that shown inFIGS. 8-9, second component 82, 92 comprises a second beam 83, 93 and asecond engagement element 86, 96. As shown in FIG. 8, and withoutlimitation, the first engagement element 85 may comprise a pin or ashaft and second engagement element 86 may comprise a socket, opening,or other geometry adapted to accept the first engagement element 85. Asshown in FIG. 9, and without limitation, the first engagement element 85may comprise socket, opening, or other geometry adapted to accept a pin,shaft or other mechanical fastener (not shown) and second engagementelement 86 may comprise a socket, opening, or other geometry adapted toaccept a pin, shaft or other mechanical fastener (not shown).

In certain implementations, the second engagement element 86 maycomprise a flange or other geometry 861 to produce a counter-force inresponse to the reaction force from 81 and thereby to resist the releaseor relaxation of the first component 81. In certain implementations, aflange or other geometry 861 is adapted to produce a counter-force onlyup to some limit and thereby to resist the release or relaxation of thefirst component 81 only up to that limit and, in the event that theforces from 81 exceed the limit, to allow 81 to become loose, escapecapture, or spring free.

In certain implementations, without limitation, the first engagementelement 85 and the second engagement element 86 may be engaged to oneanother by one or more connection methods. Connection methods maycomprise pinned connections, fixed connections, roller connections, andother form of connection. A pinned connection provides reaction forcesto substantially resist translation of the first engagement element 85and the second engagement element 86 with respect to one another, butallow or produce small resistance to the first engagement element 85 andthe second engagement element 86 to rotate with respect to one another.A fixed connection provides reaction forces to substantially resisttranslation of the first engagement element 85 and the second engagementelement 86 with respect to one another, and also provides reactionforces to substantially resist rotation of the first engagement element85 and the second engagement element 86 with respect to one another. Aroller connection may provide reaction forces to substantially resisttranslation in one or more constrained directions of the firstengagement element 85 and the second engagement element 86 with respectto one another, but allows or produce small resistance to the firstengagement element 85 and the second engagement element 86 to rotatewith respect to one another and to translate with respect to one anotherin one or more non-constrained directions.

Each of these connection methods can have performance characteristics,like all elements permitted to move with respect to one another, definedby the materials and/or by appropriate selection of bearing components.Bearing components may include, without limitation, frictionlessbearings, journal bearings, slide bearings, or other friction modifyingcomponents or materials.

In certain implementations, the first component 81 comprises more thanone of the first engagement elements 85, 87. In certain implementations,the second component 82 comprises more than one of the second engagementelements 86, 88.

Referring now to FIG. 10, in certain implementations, a support member101 may be used as part of a suspension 100 in a vehicle 109. Withoutlimitation, a suspension 100 may be connected to a vehicle 109 by saddle102 providing compliant engagement geometry between the support member101 and the vehicle 109. In certain implementations, a saddle 102comprises hard rubber, synthetic rubber, other polymers, leather, orother materials selected to provide the desired engagement between thevehicle 109 and the support member 101.

A support member 101 may comprise a first component 104 and a secondcomponent 105. First component 104 may be elastically deflectable suchthat it has some of the properties of a spring. In certainimplementations, such as, without limitation, that shown in FIG. 10,first component 104 comprises a first elongated beam 104 a adapted toundergo substantial deflection in a substantially elastic manner and afirst engagement element 104 b. Second component 105 is adapted tosubject said first component 104 to a pre-stress load and to hold saidfirst component 104 in a deflected position. In certain implementations,the pre-stress load to which the first component 104 is subjected tocomprises a first moment. In certain implementations, first component104 is adapted to subject said second component 105 to a pre-stress andto hold said second component 105 in a deflected position. Engagement ismade by deflecting the first component 104 to produce a reaction forceand capturing the first component 104 with a second component 105 suchthat either the first component 104 or the second component 105 must befurther loaded or otherwise acted upon in order to disengage the firstcomponent 104 from the second component 105. In certain implementations,such as, without limitation, that shown in FIG. 10, second component 105comprises a second elongated beam 105 a and a second engagement element105 b. Without limitation, the first engagement element 104 b and thesecond engagement element 105 b may engage one another to comprise apinned connection, a fixed connection, or other form of connection. Insome implementations, in certain implementations, such as, withoutlimitation, that shown in FIG. 10, first component 104 further comprisesa third engagement element 104 c and second component 105 comprises afourth engagement element 105 c. Without limitation, the thirdengagement element 104 c and fourth engagement element 105 c may engageone another to comprise a pinned connection, a fixed connection, orother form of connection.

Without limitation, a suspension 100 may comprise one or more dampers103. A damper 103 may comprise a conventional shock absorber, avisco-elastic damper, a hysteretic damper, or any other sort of devicethat acts to dampen vibratory motion. As shown in FIG. 10, a damper 103,may by an elongated damper engaged with the support member 101 and oneor more of first component 104 and a second component 105.

Referring now to FIG. 11, in certain implementations, a support member111 may be used as part of a bridge 110. Without limitation, a bridge110 may be engaged to a foundation 112. In certain implementations, abridge 110 may be engaged to a foundation 112 by a fixed connection, apinned connection, a roller connection, or by another connection.

A support member 111 may comprise a first component 113 and a secondcomponent 114. First component 113 may be elastically deflectable suchthat it has some of the properties of a spring, where elasticity has thetraditional engineering meaning of having an ability to resist appliedstress and return to an original shape or size when stress is removed;and where deflection has the traditional engineering meaning of thedegree to which a structural element is displaced under a stress orload. Therefore, in this example, the first component 113 beingelastically deflectable may mean that it has the ability to resistapplied stress or load in the amount and direction of the deflection,and return to its original shape and/or size when the stress or load isremoved in the amount and direction of deflection. In certainimplementations, such as, without limitation, that as shown in FIG. 11,first component 113 comprises a first elongated beam 113 a adapted toundergo substantial deflection in a substantially elastic manner and afirst engagement element 113 b. Second component 114 is adapted to holdfirst component 113 in a deflected position. In certain implementations,first component 113 is adapted to hold second component 114 in adeflected position. In this way, in one implementation, as describedabove, an appropriate load, that will overcome the elasticity of thebeam 113 a, can be applied to the first elongated beam 113 a, causingthe beam 113 a to deflect (e.g., resulting in a reduced clear span ofthe arc). Engagement is made by deflecting the first component 113 toproduce a reaction force (e.g., stress against the elasticity of thefirst component 113, or pre-stress once engaged) and capturing the firstcomponent 113 with a second component 114 such that either the firstcomponent 113 or the second component 114 must be further loaded orotherwise acted upon in order to disengage the first component 113 fromthe second component 114. In certain implementations, such as, withoutlimitation, that shown in FIG. 11, second component 114 comprises asecond elongated beam 114 a and a second engagement element 114 b.Without limitation, the first engagement element 113 b and the secondengagement element 114 b may engage one another to comprise a pinnedconnection, a fixed connection, or other form of connection.

As shown in FIG. 11, the first component 113 is subjected topre-stressing negative moment by engagement with second component 114.That is, for example, with continued reference to FIGS. 8 and 9, thefirst elongated beam 113 a may be subjected to a negative load (e.g.,stress in an opposite direction of expected load during use/operation),where the negative load is sufficient to overcome the elasticity of thebeam 113 a. In this example, application of the negative loaded canresult in deflection of the arcuate beam 113 a in the direction of theapplied negative load. As described above, when negative load is appliedto an arcuate beam, the length of the clear span (e.g., the distancebetween the end points of the arc) is reduced. In this example, thereduced clear span allows the end points, comprising the firstengagement element 113 b, to be engaged with the second engagementelement(s) 114 b disposed on the second component 114. Further, in thisexample, the distance between the second engagement element(s) 114 b isless than the distance between the first engagement element(s) 113 b ofthe first component 113. Therefore, when a sufficient negative load isapplied to the first elongated beam 113 a, and the first engagementelement(s) 113 b of the first component 113 are engaged (e.g., asdescribed above in FIGS. 8 and 9) with the second engagement element(s)114 b, disposed on the second component 114, the first elongated beam113 a should remain under the stress of the negative load, therebycreating a pre-stressed condition for the first component. Similarly, inthis example, once the first component is engaged with the secondcomponent 114, the second component will be disposed in a pre-stressedcondition, resulting from the stress applied from the first component,attempting to elastically return to its restful state (e.g., arcuatebeam). It will be appreciated that the dimensions of, and/or materialsused for, the first and second components 113, 114 can be determined bysound engineering principles, based on the intended use. For example, asdescribed above, an amount of pre-stress force applied to the firstcomponent 113 may reduce a size (e.g., cross-section surface area) ofthe first elongated beam 113 a. Further, a steel beam may be able tosustain a greater expected load than a wood beam of similar size.Additionally, a length of the span of a bridge utilizing the systemsdescribed herein will dictate the dimensions of and/or material used forthe bridge. That is, for example, a short span may merely utilize asingle set of first and second components 113, 144 so engaged, as inFIGS. 8, 9, and 11; while a larger span may utilize a plurality of suchsets of components 113, 114 so engaged. Such determinations should bemade by use of sound engineering skills applied to respective uses.

Without limitation, a bridge 110 may further comprise a deck 115 adaptedto support traffic thereupon. A deck 115 may be adapted to supportpedestrian traffic, vehicle traffic, animal traffic or other sorts oftraffic. In some implementations, the deck 115 may comprise meshwork. Adeck 115 may be engaged to a bridge by engaging it with the firstcomponent 113. In certain implementations, the deck is engaged to firstcomponent 113 by suspending or hanging the deck 115 therefrom with oneor more suspension elements 116. Suspension elements 116 may comprisecables, wires, rods, straps, ropes, links, bars, or other components. Byengaging deck 115 to the first component 113, a downward load on thedeck, such as from traffic borne thereupon, may subject the firstcomponent 113 to a positive moment. A positive moment will counteract,at least partially, the above noted pre-stress in first component 113.Accordingly, a downward load on the deck may reduce the stress in firstcomponent 113.

While the support element has been described above in connection withcertain implementations, it is to be understood that otherimplementations may be used or modifications and additions may be madeto the described implementations for performing the same function of thesupport element without deviating therefrom. Further, allimplementations disclosed are not necessarily in the alternative, asvarious implementations may be combined to provide the desiredcharacteristics. Variations can be made by one having ordinary skill inthe art without departing from the spirit and scope of the supportelement. Therefore, the support element should not be limited to anysingle implementation, but rather construed in breadth and scope inaccordance with the recitation of the attached claims.

The word “exemplary” is used herein to mean serving as an example,instance or illustration. Any aspect or design described herein as“exemplary” is not necessarily to be construed as advantageous overother aspects or designs. Rather, use of the word exemplary is intendedto present concepts in a concrete fashion. As used in this application,the term “or” is intended to mean an inclusive “or” rather than anexclusive “or.” That is, unless specified otherwise, or clear fromcontext, “X employs A or B” is intended to mean any of the naturalinclusive permutations. That is, if X employs A; X employs B; or Xemploys both A and B, then “X employs A or B” is satisfied under any ofthe foregoing instances. Further, at least one of A and B and/or thelike generally means A or B or both A and B. In addition, the articles“a” and “an” as used in this application and the appended claims maygenerally be construed to mean “one or more” unless specified otherwiseor clear from context to be directed to a singular form.

Although the subject matter has been described in language specific tostructural features and/or methodological acts, it is to be understoodthat the subject matter defined in the appended claims is notnecessarily limited to the specific features or acts described above.Rather, the specific features and acts described above are disclosed asexample forms of implementing the claims. Reference throughout thisspecification to “one implementation” or “an implementation” means thata particular feature, structure, or characteristic described inconnection with the implementation is included in at least oneimplementation. Thus, the appearances of the phrases “in oneimplementation” or “in an implementation” in various places throughoutthis specification are not necessarily all referring to the sameimplementation. Furthermore, the particular features, structures, orcharacteristics may be combined in any suitable manner in one or moreimplementations. Of course, those skilled in the art will recognize manymodifications may be made to this configuration without departing fromthe scope or spirit of the claimed subject matter.

Also, although the disclosure has been shown and described with respectto one or more implementations, equivalent alterations and modificationswill occur to others skilled in the art based upon a reading andunderstanding of this specification and the annexed drawings. Thedisclosure includes all such modifications and alterations and islimited only by the scope of the following claims. In particular regardto the various functions performed by the above described components(e.g., elements, resources, etc.), the terms used to describe suchcomponents are intended to correspond, unless otherwise indicated, toany component which performs the specified function of the describedcomponent (e.g., that is functionally equivalent), even though notstructurally equivalent to the disclosed structure which performs thefunction in the herein illustrated exemplary implementations of thedisclosure.

In addition, while a particular feature of the disclosure may have beendisclosed with respect to only one of several implementations, suchfeature may be combined with one or more other features of the otherimplementations as may be desired and advantageous for any given orparticular application. Furthermore, to the extent that the terms“includes,” “having,” “has,” “with,” or variants thereof are used ineither the detailed description or the claims, such terms are intendedto be inclusive in a manner similar to the term “comprising.”

1. A vehicle suspension comprising, a support member engaged with avehicle, a first component engaged to said support member, said firstcomponent comprising: a first elongated beam adapted to undergosubstantial deflection in a substantially elastic manner; a firstengagement element; and a third engagement element; wherein said firstcomponent is subject to a first pre-stress load, wherein said firstpre-stress load comprises a first moment, wherein said first momenttends to bend said first elongated beam into an arcuate form; a secondcomponent engaged to said first component, said second componentcomprising: a second elongated beam adapted to undergo substantialdeflection in a substantially elastic manner; a second engagementelement, engaged to said first engagement element by a first connection;and a fourth engagement element, engaged to said third engagementelement by a second connection; wherein said second component is subjectto a second pre-stress load; and wherein, during operation of saidvehicle, said vehicle is adapted to apply an operational load to thefirst component, and wherein said operational load at least partiallyrelaxes the first moment.
 2. The vehicle suspension of claim 1, furthercomprising an elongated damper, wherein said damper comprises: a firstend engaged with said support member; and a second end engaged with saidfirst component or said second component.
 3. The vehicle suspension ofclaim 2, wherein said first connection and said second connectioncomprise pinned connections.